Double metal cyanides complexed with an acyclic aliphatic saturated monoether,an ester and a cyclic ether and methods for making the same



United States Patent O DOUBLE METAL CYANIDES COMPLEXED WITH AN ACYCLIC ALIPHATIC SATURATED MONO- ETHER, AN ESTER AND A CYCLIC ETHER AND METHODS FOR MAKING THE SAME Robert J. Herold, Akron, Ohio, assignor to The General Tire & Rubber Company, Akron, Ohio, a corporation of Ohio No Drawing. Original application Feb. 14, 1963, Ser. No. 258,603, now Patent No. 3,278,459, dated Oct. 11, 1966. Divided and this application Jan. 13, 1966, Ser. No. 532,487

US. Cl. 260429 13 Claims Int. Cl. C08g 23/00; B01j 11/00 ABSTRACT OF THE DISCLOSURE A double metal cyanide complex compound is provided, wherein one of the metals of said complex compound is selected from the group consisting of Zn (II), Fe (II), Fe (111), C (II), Ni (II), Mo (IV), Mo (VI), Al (III), V (IV), V (V), Sr (II), W (IV), W (VI), Mn (II), and Cr (III), and mixtures thereof, and wherein the other metal of said complex compound is selected from the group consisting of Fe (II), Fe (III), Co (II), Co (III), Cr (II), Cr (in Mn (11), Mn (III), V W), and V (V), and mixtures thereof, containing, in an amount sufficient to increase the activity of said complex for the polymerization of organic cyclic oxides, at least one organic material selected from the group consisting of an ester, a cyclic ether and an acyclic aliphatic saturated monoether, said organic material being inert to polymerization by said compound and further being complexed with said compound, said compound containing at least a majority of CN- bridging groups. These compounds are useful in polymerizing epoxides such as propylene oxide, ethylene oxide, allyl glycidyl ether and the like to make polyethers.

This is a division of application Ser. No. 258,603, filed Feb. 14, 1963, now United States Patent No. 3,278,459 granted Oct. 11, 1966. r

The present invention relates to double metal cyanide complexes useful as catalysts and to methods for making said catalysts.

It is an object of the present invention to provide double metal cyanide complexes useful as catalysts.

It is another object of this invention to provide a method for making double metal cyanide complexes useful as catalysts.

These and other objects and advantages of the present invention will become more apparent to those skilled in the art from the following detailed description and examples.

According to the present invention it has been discovered that certain double metal cyanide complexes are useful as catalysts (or as initiators as they can be consumed during polymerization) for the polymerization of organic compounds having at least one ring of from 2 to 3 carbon atoms and one oxygen atom like ethylene oxide, propylene oxide, allyl glycidyl ether, oxetane, and so forth.

Many of the polymers obtained by the method of this invention are entirely or almost entirely amorphous in contrast to the polymers of similar organic oxides obtained using other catalysts. On the other hand, some of the polymers obtained such as those from isobutylene oxide are entirely crystalline or resinous so that they can be used to make hard and tough articles of manufacture. The rubbery polymers prepared using the catalysts of this invention are free of gel. In certain cases 3,427,335 Patented Feb. 11, 1969 "ice where diepoxides or dioxetanes are also copolymerized with the epoxide or oxetane monomers some gel may be observed. Although these rubbery or elastomeric polymers when unstretched are amorphous as shown by X-ray, they do show some indication of orientation on stretching. Many of these polymers are linear and have very little branching depending on the type of monomers used. Polymers having very high viscosities are obtained by the present invention which still are millable, forming smooth sheets on the rubber mill, processable, extrudable and so forth. Gum stocks exhibit high elongation and are snappy. In contrast to many polymers, the polymers of the present invention exhibit high solution viscosities yet low Mooney viscosities. These rubbers, also, exhibit the good low temperature stiffening properties of the nitrile rubbers.

A tubeless tire comprises a tread portion and side walls which may be extruded from one piece of stock. The tread or the entire rubbery material of a tire can be one of the amorphous polymers or copolymers of this invention. Of course, when white sidewall tires are being made, i

the tread and sidewalls can be extruded separately. There can be one or more plies depending on the service for which the tire is designed. The fabric plies comprise rayon or nylon fabric or other textile fabric calendered or coated with rubbery material. The ends of the fabric plies are generally wrapped around beads which can comprise steel wires, and the inner surface of the tire contains a layer of a butyl rubber (a copolymer of about 99.5% isobutylene and the balance a diolefin of from 4 to 8 carbon atoms) compound or composition or other suitable material (such as a copolymer of the present invention of the desired thickness) forpreventing diffusion of air or gas from the interior of the tire. The butyl may be precured or partially precured. Where the tire is to be used with a tube, the butyl liner can be omitted. The tire can be built by conventional procedures on the usual tire building machinery and cured under pressure in suitable molds at from about 280 to 310 F. for from about 15 to 60 minutes or more. The various plies, tread stock and so forth can be tackified with heptane or similar solvents, or with adhesives of a polymer of this invention as a 15% solids in a solvent such as heptane, at the time they are laid up on the building drum. Cushion stock and inserts can be added during tire building between the breaker, if used, and the various plies as necessary to improve riding and wearing qualities as well as to obtain the desired contour and cross section in the finished tire. Chafer strips,'also, can be added during the building operation in the vicinity of the beads to minimize chafing caused by contact with the rim. All of the rubbery material employed in making the tire can be of one or more of the polymers or copolymers of the present invention. Moreover, the tread, sidewalls, and ply stocks can be of the same or a different polymer (in which the monomers or proportions thereof are varied) of the present invention depending upon the properties required in the particular structure involved. Various curing systems can be used with these compositions to get the desired degree of curing in the final tire.

Where the carcass or one or more of the ply stocks, side-walls and the like are made of a rubbery material other than that of the present invention such as a rubbery copolymer of butadiene-l,3 and styrene, natural rubber, cispolyisoprene, cispolybutadiene-l,3 and so forth as well as blends thereof including those with reclaim rubber, adhesives or cements containing those rubbers with varying amounts of the rubbery polymers or copolymers of this invention can be used if necessary to obtain the desired adhesion between the other rubbery compositions and the rubbery copolymers of the present invention. For example, where it is desired to join an extruded tread and sidewall stock of a composition of a rubbery polymer of this invention, for example a rubbery polymer or propylene oxide (P0) or a rubbery copolymer of propylene oxide and allyl glycidyl ether (AGE), to a carcass of a rubbery butadiene-l,3/styrene (BDN-STY) copolymer stock, a layer of a cement of a major amount of the BDN-STY copolymer and a minor amount of the PO-AGE copolymer is brushed on the outer surface of the carcass and dried. Next, a cement layer of about equal portions of the BDN-STY copolymer and the PO-AGE copolymer is applied to the first layer and dried followed by a third layer of a minor amount of BDN-STY copolymer and a major amount of the PO-AGE copolymer and dried. This last layer is designed to be in contact with the tread and sidewall when assembled. The carcass having the three layers of cement is then ready for application of the side walls and tread. After final assembly and curing, the tread and sidewalls adhere to the carcass. Where the tread, sidewalls, ply stocks and others are made of blends of the polymers of the present invention and natural rubber, rubbery butadiene-1,3/styrene copolymers etc., one or more similar cement layers can be used if desired.

The catalyst is most usefully prepared by reacting a transition metal cyanide complex with a metal salt in aqueous media. Removal of a substantial amount or all of the water present in the catalyst is very desirable to enhance the activity of the catalyst although it would appear that removal of all the water is not practicable and may not be desirable. One way to remove most of the water and to enhance even further the activity of the catalyst is to treat it with an additional complexing or coordinating material such as an alcohol, ether, ester, sulfide, ketone, aldehyde, amide and/or nitrile.

In general the catalysts employed in the present invention have the following rational formulae:

M is a metal ion that forms a metaloxygen bond that is relatively more stable than the coordinate bond between the metal and the nitrogen atom of the cyano, CN, group. On the other hand, M is a transition metal ion that has more than one stable valence form and forms a relatively strong covalent bond with the carbon atom of the CN group. An individual catalyst can contain more than one type of M or M metal ion in its structure. The grouping of these metals, with the cyanide ion sharing electrons with the two metal ions, usually exists in polymeric form as follows: (--MCN M NCM) where n is a number, and super S-dimensional polymers can be formed depending on the coordination numbers of M and M. Moreover, of those metal ions that produce active cyanide catalysts, all can coordinate with six groups. Most of the hexacyanoferrates (III), including zinc hexacyanoferrate (III), have a cubic face-centered lattice as the basic structure.

The CN- group in the catalyst is the bridging group, and can constitute all of the bridging groups in the catalyst. However, other bridging groups can be present in the catalyst so long as the catalyst contains at least a majority of CN- bridging groups. Thus, r and t are numbers and r is greater than t. t is zero when only the CN group is the bridging group. Other bridging groups, X in the right hand formula above, which can be present with the CN- group, can be P, Cl-, Br, 1-, OH, NO, 0 CO, H O, N0 1 C 0 or other acid radical, S0 CNO- (cyanate), CNS- (thiocyanate), NCO- (isocyanate), and NCS (isothiocyanate) and so forth.

In the above formulate M is preferably a metal selected from the group consisting of Zn (II), Fe (II), Fe (III), Co (II), Ni (II), Mo (IV), Mo (VI), A1 (III), V (IV), V (V), Sr (H), W (IV), W (VI), Mn (II) and Cr (III).

On the other hand, M is preferably a metal selected from the group consisting of Fe (II), Fe (III), Co (II), Co (III), Cr (II), Cr (HI), Mn (II), Mn (In), V (W and V (V). Also, a, b and c are numbers whose values are functions of the valences and coordination numbers of M and M, and the total net positive charge on M times a should be equal essentially to the total net negative charge on [M(CN) or [M[(CN),(X) times 0. In most instances b corresponds to the coordination number of M and is usually 6.

. Examples of catalysts which fall within the above description and which may be used are zinc hexacyanoferrate (III), zinc hexacyanoferrate (II), nickel (II) hexacyanoferrate (II), nickel (II) hexacyanoferrate (III), zinc hexacyanoferrate (III) hydrate, cobalt (II) hexacyanoferrate (I I), nickel (II) hexacyanoferrate (III) hydrate, ferrous hexacyanoferrate (III), cobalt II) hexacyano cobaltate (III), zinc hexacyano cobaltate (II), zinc hexacyanomanganate (II), zinc hexacyano chromate (III), zinc iodo pentacyanoferrate (III), cobalt (II) chloropentacyanoferrate (II), cobalt II) bromopentacyanoferrate (II), iron (II) fluoropentacyanoferrate (III), zinc chlorobromotetracyanoferrate (III), iron ('III) hexacyanoferrate (III), aluminum dichlorotetr-acyanoferrate (III), molybdenum (IV) bromopentacyanoferrate (III), molybdenum (VI) chloropentacyanoferrate (II), vanadium (IV) hexacyanochromate (II), vanadium (V) hexacyanoferrate (III), strontium (II) hexacyano manganate (III), tungsten (IV) hexacyano vanadate (IV), aluminum chloropentacyano vanadate (V), tungsten (VI) hexacyanoferrate (III), manganese (II) hexacyanoferrate (II), chromium (III) hexacyanoferrate (III), and so forth. Still other cyanide complexes can be used such as Zn[Fe(CN) NO], Zn [Fe(CN) NO Zn[Fe(CN) CO],

Al[Oo(CN) CNO], Ni [Mn(CN) CNS] and the like. Mixtures of these compounds can be employed.

In general, the complex catalysts of this invention are prepared by reacting aqueous solutions of salts which give a precipitate of a metal salt of a transition metal complex anion. For example,

where M is a metal ion which precipitates complex anion salts e.g., Zn++. a, b and c in this equation are numbers but are not necessarily equal on both sides of the equation since their values, again, are functions of the valences and coordination numbers of M, M and M and possibly Y and Z. Z is a halide or other anion e.g. Cl; M" is a hydrogen ion or a metal ion whose complex anion salts are soluble in water or other solvent e.g., K+ or Ca++; M is a complexing transition metal ion, e.g. Fe+++; and Y is a complexing anion, e.g. CN. Excess M Z may be used.

Little if any of the other bridging groups or ligands which can be used to replace part of the cyano groups (CN-) are usually introduced into the complex by use of the salt MaZ. Rather, they are introduced into the complex by employing the M[M(Y) salt containing the ligand or more correctly a salt having the formula M[M((CN) (X) in which t is a number dependent on the valence of M and the other symbols used are the same as identified above. For example, instead of potassium ferricyanide, K Fe(CN) there are used 2( )5 3( )5 2), z( )5 2( )5 2 3( )5 3( )4 K (Co(CN) I), K (Co(CN) OH), Na (Co(CN) CNO), Na (Co(CN) (CNS) Ca (Fe(CN) NCO) and so forth. Examples of the preparation of such starting materials are:

and

(II) K Fe (CN CI+H O K Fe (CN H O-l-Kcl. They, also, may be prepared by boiling a material such as K Fe(CN) in aqueous KCl, oxalic acid or other salt and so forth. Still other methods can be used. For example, see Cyanogen Compounds, Williams, 2nd ed., 1948, Edward Arnold and Co., London, p. 252 and elsewhere.

The salts should be reacted in substantial concentration in aqueous media at room temperature and, also, preferably in air or under atmospheric pressure. However, heat can be used and the catalyst can be prepared under conditions substantially or entirely free of oxygen. The salts which are used are the chloride, fluoride, bromide, iodide, oxynitrate, nitrate, sulfate or carboxylic .acid salt, such as the acetate, formate, propionate, glycolate and the like salt of a M element of the group as defined above or other M salts and mixtures thereof. Preferred are the M halide salts or halide salt forming materials since they provide catalysts having the best activity. An excess of the M salt is usually reacted with a Na, K, Li, Ca etc. M cyanide compound and so forth. Mixtures of these salts can be used.

If the resulting precipitate is then just filtered or otherwise separated from the water, preferably by using a centrifuge and dried without further washing, it has been found that the precipitated complex is noncatalytic, that is, it fails to polymerize the organic oxides in any practical amount.

Apparently extraneous ions in the solution used to form the precipitate are easily occluded with the complex. Anions (Cl etc.) coordinate to the positively charged metallic ions in the lattice, and cations (K+) coordinate to the negatively charged nitrogen atoms of the cyanide bridging groups. These ions, especially those anions coordinating to or associated with the M atom, inhibit catalytic activity or prevent the complex from causing appreciable polymerization. Additionally, these ions, for example easily ionizable Cl, may terminate the polymer chain.

On the other hand, if the complex is treated or washed one or more times with water, some or a substantial number of these occluded ions are removed from the precipitate or from the surface of the crystal lattice and the complex becomes an active catalyst for the polymerization of organic cyclic oxides. It is desired to remove all or a substantial amount of these occluded ions to enhance as much as possible the catalytic activity of the complex. However, from a practical standpoint it may not be possible to remove all of them due to the steps and times required. Moreover, some of these ions are probably trapped in the crystal lattice and cannot be removed easily. However, their presence should be reduced as much as possible. After the water wash the complex will have an appreciable amount of water depending on the number of washings and the degree of drying following water washing. These resulting catalysts will then have the following rational formulae:

where d is a number and where M, M, CN, X, a, b, c, r and t have the significance as defined supra. If the catalyst is dried or gently heated for extended periods of time d can be or approach zero.

Moreover, to obtain the best activity of the catalysts for polymerization, an organic material is added to the catalyst precipitate preferably before it is centrifuged or filtered, is mixed with the water during washing of the precipitate, is used alone as the washing medium provided it replaces or dissolves occluded ions, or is used to treat or wash the precipitate after it has been washed with water to replace at least a portion of the water. Sufiicient of such organic material is used to eifect these results in order to activate and/ or enhance the activity of the catalyst. Such organic material, also, should desirably coordinate with the M element or ion and should desirably be one or more relatively low molecular weight organic materials. The organic material should preferably be water miscible or soluble or substantially so, have a substantially straight chain or be free of bulky groups and have up to 18 carbon atoms, even more preferably only up to 10 carbon atoms, and be a liquid at room tem perature.

Examples of organic materials for use in treating the double metal cyanide catalyst to afford polymers of inherent viscosities in isopropanol of up to about 2.5 are alcohols, aldehydes and ketones such as methanol, ethanol, propanol, isopropanol, butanol, hexanol, octanol, and t-butyl alcohol; formaldehyde, acetaldehyde, propionaldehyde, butyraldehyde, i-butyraldehyde, glyoxal, benzaldehyde and tolualdehyde; and acetone, methyl ethyl ketone, 3-pentanone, Z-pentanone, and 2-hexanone. Ethers such as organic cyclic polyethers are also useful affording generally polymers of intrinsic viscosities up to about 3.6. Examples of such cyclic ethers are m-dioxane, p-dioxane trioxymethylene, paraldehyde and so forth. Aliphatic saturated monoethers are also useful. Acyclic aliphatic polyethers are preferred since catalysts treated with them afiord polymers having instrinsic viscosities of from about 4 to about 7. Examples of such ethers, such as aliphatic ethers, are ethyl ether, l-ethoxy pentane, bis-(bchloroethyl) ether, bis-(b-ethoxy ethyl) ether or diglyet, butyl ether, ethyl propyl ether, bis (b methoxy ethyl) ether or diglyme, ethylene glycol dimethyl ether, triethylene glycol dimethyl ether, dimethoxy methane, acetal, methyl propylether, diethoxymethane, octaethylene glycol dimethyl ether and so forth of which the acyclic polyethers are preferred. Still other organic complexing agents can be used such as the amides, esters, nitriles and sulfides of which the following are examples: formamide, acetamide, propionamide, butyramide, and valeramide; amyl formate, ethyl formate, n-hexyl formate, n-propyl formate, ethyl ethanoate, methyl acetate, ethyl acetate, methyl propionate, and triethylene glycol diacetate, acetonitrile, propionitrile and butyronitrile; and dimethyl sulfide, diethyl sulfide, dibutyl sulfide, dipropyl sulfide, and diamyl sulfide and so forth. Preferred are ethers having more than one oxygen atom and which form a chelate bond with respect to M. Mixtures of these organic treating agents can be used. Excess of these organic treating agents which are not complexed with the catalyst, especially the high boiling compounds, can be removed by extraction with pentane, hexane and so forth.

After treatment with the above organic material the catalysts have the following rational formulae:

In these formulae d can be a number, fractional number, or zero and e is a number which, since the catalyst is a nonstoichiometric complex in which various amounts of H 0 and R may be bonded to the various Ms, may be a fractional number rather than an integer. e is zero when the complex is not treated with R. R is one or more of the complexing organic amides, alcohols, aldehydes, esters, ethers and so forth shown above. M, M, CN, X, a, b, c, r and t have the significance as discussed above. In general, d and :2 will have values corresponding at least in part to the coordination number of M. However, both the H 0 and R can be occluded in the crystal lattice. In general the sum of the oxygen, nitrogen and/ or sulfur or other coordinating atoms of H 0 and R (depending on the organic complexing agent) is equal to from about 0.1 up

to about 5.0 g-atoms maximum per g-atom of M. Subsequent drying or heating of the catalyst to remove all of the H and/ or R results in a loss or a substantial decrease in the catalytic activity of the catalyst.

As shown by the previous formulae if the organic complexing material is not used, R will not be present, and hence, e can be zero. Thus, the general formula for these catalysts is M,,(D),,(H O) -(R) where M, H O, R, a, c, d, and e have the significance as indicated above, where d and 2 also can be or approach zero, where D is selected from the group consisting of M(CN) and and where M, CN, X, b, r and t have the significance as indicated above. With regard to the subscripts in the above formulae, number includes whole numbers as well as fractional numbers.

It is to be noted that if the catalyst is merely filtered or centrifuged from the solution in which it was prepared and washed with one of the polymerizable cyclic oxide monomers, it shows little or no catalytic activity for subsequent polymerization of said monomers. On the other hand, if the catalyst is washed with water and the ether, or the ether or other organic complexing compound as described above, and subsequently with one of the polymer izable cyclic oxide monomers a storable initiator for polymerization is obtained.

After the washing steps the precipitate or catalyst can be used as such. However, it is preferred to dry it to remove excess treating agent and any remaining easily removable H O and to provide it in a form which is easily handled. Such drying is readily accomplished by subjecting the catalyst to a vacuum or by heating it in air or in an inert atmosphere at a temperature up to about 100 C. It is much preferred to dry under a vacuum (for ex- 3 ample 0.5-1 mm. Hg) at low temperature, for example about room temperature C.) or in a stream of air, nitrogen or inert gas at 25 C. or at least at a temperature above about 5 C. The heat-treated catalyst has generally to be used at higher concentrations than the vacuumtreated catalyst. As the temperature during drying is increased, the activity of the catalyst for polymerization is decreased. Thus, high temperatures are to be avoided. 200 C. may be considered as a maximum temperature. During heat treatment it is believed that some of the oxygenated and other organic treating compounds weakly coordinated to M may be lost to leave voids in the crystal lattice, and the atoms in the crystal lattice may rearrange to satisfy the coordination requirements of the metals.

Heating may also remove CN (CN) and reduce M.

Also, the molecular Weight of the catalyst can increase, and the number of exposed metal ions on the surface of the catalyst or the active sites can be reduced, thus reducing the activity of the catalyst for epoxide and oxetane polymerization. It, thus, is preferred that the drying step leave as many as possible M ions exposed in the lattice of the complex and that the catalyst be in finely divided or particulate form to obtain the best results for polymerization. Moreover, freshly prepared (precipitated, washed and dried) catalysts are preferred rather than catalysts which have been aged or stored for extended periods of time since the catalysts decompose slowly when stored. The catalyst can be stored for longer times at lower temperatures.

The organic cyclic oxides to be polymerized include any cyclic oxide having an oxygen-carbon ring in which an oxygen atom is joined to 2 or 3 carbon atoms in the ring which will open and polymerize with the same or other cyclic oxide monomers and having up to a total of 70 carbon atoms or more. These monomers, also, may contain 1,2 or more, preferably only 1, aliphatic carbonto-carbon double bonds. The alkenyl, nitro, ether, ester and halogen (except easily ionizable halogen substituted derivatives) substituted derivatives of these cyclic oxides can likewise be employed. The use of monomer mixtures having cyclic oxide monomer(s) containing aliphatic carbon-to-carbon double bond unsaturation in minor amounts, the balance being the saturated cyclic oxide monomer(s), permits the resulting copolymer to be cured readily with materials such as sulfur and the like. A very useful mixture is one containing propylene and/or 1,2- butylene oxide or other saturated oxide in an amount of from about to 99.5 mol percent and allyl glycidyl ether, vinyl cyclohexene monoxide and/or butadiene monoxide or other unsaturated oxide in an amount of from 20 to 0.5 mol percent to obtain a crosslinkable (by sulfur) copolymer. Minor amounts, about 05-20 mol percent, of a third, fourth or fifth etc. monomer, replacing part of the propylene oxide and/or allyl glycidyl ether etc. such as 1,2-butene oxide, 2,3-hexene oxide etc. of from 4 to 12 carbon atoms, can be used in making the copolymer to break the lengths of isotactic units in the copolymer which are too short to be measured by X-ray. This may be desirable, where only small amounts of an unsaturated monomer are used, to obtain more flexibility in processing and molding. These cyclic oxides should be pure or essentially pure to obtain the best results or they should be free or essentially free of materials like H O which may inhibit polymerization.

Examples of useful cyclic oxides are ethylene oxide (1,2-ep0xy ethane), propylene oxide, 1,2-butene oxide (or 1,2-epoxy butene), 2,3-butene oxide, 1,2-dodecane monoxide, isobutylene monoxide, styrene oxide, 1,2-pentene oxide, isopentene oxide, 1,2-diisobutylene oxide, 1,2- hexene oxide, 2,3-hexene oxide, 1,2-heptene oxide, allyl glycidyl ether, isoheptene oxide, octene oxide, nonene oxide, decene oxide, hendecene oxide, methyl glycidyl ether, ethyl glycidyl ether, vinyl cyclohexene monoxide, nitro ethylene oxide, phenyl glycidyl ether, 3-methyl-3,4- epoxy butene-l, butadiene monoxide, glycidyl methacrylate, 2,3-diisobutylene oxide, dicyclopentadiene monoxide, isoprene monoxide, oxetane (C H O), tolyl glycidyl ether, 3,3-dimethyl oxetane, 3-n-nonyl oxetane, 3-allyl-3-methyl oxetane, 3-vinyl-3-methyl oxetane, pentadecene oxide, 3,3-diethyl oxetane, 3-ethyl-3-butyl oxetane, 3-chloromethylene oxetane, 3-chloro methyl-3-niethyl oxetane, 3- methyl-3-ethyl oxetane, 1,2-epoxy pentacosane, 1,4-dichloro-2,3-epoxy butane, allyl epoxy stearate, 1,2-hexacontene oxide, 1,2-heptacontene oxide and other cyclic oxides. These cyclic oxides should preferably have a total of from 2 to 25 carbon atoms, Of these materials it is even more preferred to use the lower molecular weight cyclic oxides such as ethylene oxide, propylene oxide, butylene oxide, etc. containing from 2 to 12 carbon atoms with minor amounts of unsaturated cyclic oxides, such as allyl glycidyl ether, butadiene monoxide and vinyl cyclohexene monoxide, etc. containing up to 12 carbon atoms. Mixtures of 2, 3, 4, 5 or more of these cyclic oxides can be used for polymerization.

One or more of the above cyclic oxides can be reacted with one or more cyclic oxides having 2, 3 or more rings of from 2 to 3 carbon atoms and 1 oxygen atoms, preferably in a minor molar amount. Examples of these cyclic oxides (ie, di, tri, etc. epoxides and/or oxetanes) are: butadiene dioxide, vinyl cyclohexene dioxide, limonene dioxide, the diglycidyl ether of bisphenol A, the diglycidyl ether of pentanediol, the reaction product of the diglycidyl ether of pentanediol and bisphenol A, the reaction product of the diglycidyl ether of pentanediol and a polyalkylene and/or arylene ether glycol (3,4- epoxy-6-methyl cyclohexyl methyl)-3,4-epoxy-6-methyl cyclohexane carboxylate, 1-epoxyethyl-3,4-epoxy cyclohexane, diglycidyl ether, bis(3-oxetane)butane, bis(3-oxetane)hexane, dipentane dioxide the reaction product of epichlorohydrin and trihydroxyl diphenyl dimethyl methane, the reaction product of epichlorohydrin and phloroglucinol, the reaction product of epichlorhydrin and erythritol, the reaction product of 3-chloro oxetane and bisphenol A, the reaction product of 3-chloro oxetane and trihydroxyl diphenyl dimethyl methane, the re- OH O Oxetanes also are well known. They can be made by the preparation of a NaOH solution of a 1,3-glycol which is then dripped into sulfuric acid to close the ring and split out water. An alternative method is as follows:

CHsCO OH HCl HOCH2CH2CH2OH HOCH2CH2CH2C1 HzC-CH? KOH CIH2CCHQCH2OCOCH3 trimethylene oxide, H2 Another method is to heat a dialdehyde in the presence of acetaldehyde and aluminum isopropoxide; distill off the acetone to get the aluminum salt; hydrolyze to remove the aluminum to obtain and then add this compound to a NaOH solution and drip the solution into sulfuric acid to obtain ring closure and the splitting out of H 0.

The catalyst is used in a minor amount by weight only sufficient to catalyze the reaction. Large amounts are usually wasteful and may in time cause reversion or subsequent decomposition of the polymer. In general, there is used a total of from about 0.001 to by weight of the catalyst based on the total weight of the polymerizable cyclic oxide monomer or monomers employed during polymerization. However, it is preferred to use from about 0.01 to 0.50% by weight of the catalyst based on the total weight of the monomer(s) The monomers may be polymerized with the catalyst in mass, or in solvent '(Which can facilitate handling and transfer of heat). They, also, should be polymerized under inert and/ or non-oxidizing conditions, for example, under an atmosphere of nitrogen, argon, neon, heliurn, krypton or other inert atmosphere. Alternatively, the inert gas can be omitted and the monomer polymerized only under pressure from any vaporized solvent if used or vaporized monomer. In some instances the polymerization can be conducted in polymerizers open to the air provided the air is free of materials which would inhibit polymerization (i.e., conversion or molecular weight) and especially free of H 0, although this procedure can be hazardous for some of the monomers are flammable. The monomer should be soluble in the solvent which should be an inert or non-reactive solvent. Examples of useful solvents are heptane, octane, cyclohexane, toluene, benzene, trimethylpentane, n-hexyl chloride, n-octyl chloride, carbon tetrachloride, chloroform, trichlor-oethylene etc. Since many of the reactants are volatile the polymerization should be conducted in a closed container and may be under pressure. The reactor is preferably operated at a total pressure of 1 atmosphere or somewhat less. Polymerization can be conducted at temperatures of from about 0 C. to 100 C. although somewhat wider temperature ranges can be used. Preferably temperatures of from about C. to C. are used for polymerization. An induction period of about %2 hours or more may be observed with some of the catalysts. If the polymer dissolves in the solvent, it can be precipitated with a non-solvent and recovered, or the solvent can be separated from the polymer by distillation or evaporation. The catalyst or catalyst residues can be removed if desired by dissolving the polymer in a solvent, adding dilute aqueous KOH and then reprecipitating or by treating a solution of the polymer with H O or NH OH and centrifuging. The necessity of removal of the catalyst will depend upon the ultimate use of the polymer. It is very desirable to polymerize while agitating the monomer(s), catalyst and solvent, if used.

Since the reaction is exothermic and since some monomers may polymerize very rapidly in the presence of the catalyst, it may be desirable to reduce the concentration of the catalyst or to use a solvent as above as diluent.

Gel formation during polymerization with unsaturated monomers is not usually observed using the double metal cyanide catalysts, and consequently gel inhibitors are not normally required. Antioxidants or antidegradants such as phenyl beta naphthylamine, PBNA, or other antidegradants are desirably added prior to or after polymerization to avoid degradation which might occur in the presence of these catalysts which may catalyze oxidation. PBNA may be used in an amount by weight approximately equal to the amount of the catalyst during polymerization. Some antidegradants may retard polymerization and should be added after polymerization.

The polymers and copolymers etc. obtained by the method of the present invention have an average molecular weight of at least 20,000. Most of them have a high average molecular weight of from about 500,000 to 1,000,000 or higher, as shown by their high viscosities. As an indication of the amorphous nature of most of these polymers a rubbery copolymer of about 97 mol percent propylene oxide and 3 mol percent allyl glycidyl ether is relatively soft and gives low tensile values (about 350' p.s.i.) when cured as a gum stock. When loaded with 40 p.p.h. of HAF black, tensile strengths of up to 2300 p.s.i. are observed. X-ray diffraction of the black loaded cured stock when stretched showed a low degree of crystallinity.

The resinous and rubbery polymers of this invention are useful as coatings or impregnants for fabrics, films for packaging materials, belts, elastic fibers, adhesives, hose or tubing, and in making tires, shoe heels, raincoats, rubbery laminates, upholstery materials, floor mats and tiles, carpet and rug backings, gaskets, molded articles, golf ball covers, centers and cores, sponges or other cellular products, encapsulating compounds and the like. Low molecular weight solid or grease-like polymers of this invention are useful as plasticizers and extenders for natural and synthetic resins and rubbers as well as for the high molecular weight polymers of the present invention.

The polymers may be compounded or mixed with the usual rubber and resinous compounding materials such as curing agents, anti-degradants, fillers, extenders, ultraviolet light absorbers, fire resistant materials, dyes, pigments, plasticizers, lubricants, other rubbers and resins and the like. Examples of useful materials which can be compounded with these rubbers, resins and polymers are zinc oxide, stearic acid, zinc stearate, sulfur, organic peroxides, 2-mercapto-benzothiazole, bis-(morpholyl) disulfide, bis(benzothiazyl) disulfide, zinc dimethyl dithiocarbamate, tetramethyl thiuram disulfide, carbon black, TiO iron oxide, calcium oxide, SiO and SiO containing materials, aluminum oxide, phthalocyanine blue or green, asbestos, mica, wood flour, nylon or cellulose fibers or flock, clay, barytes, dioctyl phthalate, trieresyl phosphate, non-migrating polyester plasticizers, phenyl beta naphthylamine, pine oil, mineral oil, hydroquinone monobenzyl ether, mixtures of octylated diphenyl-amines, styrenated phenols, aldol alpha naphthylamine, diphenyl amine acetone reaction products, antimony oxide, asphalt, coumarone indene resin, natural rubber, polyisoprene, butadiene-styrene rubber or resin, polyethylene-propylene rubbers, a 60/ 30/ 10 ethylene propylene butadiene terpolymer, nitrile rubber, polybutadiene, acrylonitrile-styrene resin, polyesters, polyethers, polyester and/or ether urethanes, polyvinyl chloride and the like and mixtures thereof. Polymers of the present invention may be cured by sulfur and the like or sulfur furnishing materials, organic peroxides, other curing and crosslinking materials, irradiation and so forth.

It is not precisely known what occurs to make the double metal cyanide complexes, especially those treated with the above organic complexing materials (ether, etc.), so useful in polymerizing organic cyclic oxides. While the following discussion relates to treatment of the double metal cyanide catalyst with ethers, it will be appreciated that it will generally also apply to treatment of such catalyst with the other organic treating agents shown above. It has been shown that, for example, with respect to zinc hexacyanoferrate, as an illustration, when the precipitate is washed with dioxane, a more effective catalyst is produced. During this treatment with dioxane it is believed that a number of reactions takes place: (1)

some of the chloride ions in the lattice are oxidized, re-

sulting in the reduction of Fe(III) to Fe(II); (2) the chloride from reaction (1) reacts with the water and ether present during the wash-treatment to give Cl, and chlorinated ether; (3) the successive washes remove some of the products of reaction (2); and (4), the oxygen atoms of the ether apparently coordinate to the zinc ions in the lattice, rearranging the lattice structure by inserting dioxane groups between the zinc ions as follows:

Thus, in the case of some of the dioxane-zine hexacyanoferrate complexes, elemental analyses revealed that they were apparently non-stoichiometric complexes having the formula Zn; [Fe(CN) (C H O (H O) where y=1 to 2 and x=2.5 to 3.1. According to infrared and elemental analyses some of the dioxane in the complex may be chlorinated and some of the H may be in the form of OH, or O groups. As ordinarily prepared, these complexes generally contained from about 4 to 5% Cl and a smaller amount of K+.

If the catalyst is prepared with Zn(NO instead of ZnCl approximately of the normal amount of dioxane is incorporated in the catalyst. This catalyst is not as effective as the one prepared from the chloride as shown by Example 2 I below.

Although a great :part of the iron in the ether (or other organic complexing moiety) -zinc hexacyanoferrate complex is believed to be FE(II), as a result of the oxidationreduction reaction that occurs during preparation, the dioxane complex prepared from ZnCl and K Fe(CN) is not as active even at polymerization temperatures of C. Analyses showed that a reduced amount of dioxane was incorporated in such complexes and the chlorine content was high.

The reduced catalytic eifect when using Zn(NO or K Fe(CN) in the preparation of the catalyst complex is apparently related to the mechanism of the ether-hexacyanoferrate reaction. This mechanism may be viewed as follows. As the chloride ions of the surface zinc ions in the crystal lattice transfer electrons into the Zn NC- Fe grouping, ether molecules can displace the resulting chlorine atoms and form ether-zinc coordinate bonds. For example, Zn [Fe(CN) (KCl) -|-yROB-+Zn Ky [Fe(CN) (ROR) +yCl (Note: y in the above equation may not be same as in the preceding formulae).

The driving force for this reaction is the removal of C1 by solution of the gas in the water and ether and the reaction of C1 with the ether.

This oxidation-reduction reaction and displacement of the chlorine by ether is accompanied by a change in the crystal lattice. According to elemental and infrared analyses, most of the zinc ions in the lattice appear to form coordination bonds with from 1 to 4 oxygen atoms. The oxygen atoms of both the water and the ether are in- 12 volved in this coordination. X-ray analysis and density measurements appeared to confirm this lattice change. Thus, the oxygen atoms of the ether complete with the CN groups of the Fe(CN) anion to produce a polymeric structure with more exposed zinc ions as shown below:

This process of opening up the lattice is aided by the presence of water during the ether treatment. Apparently, the water dissolves Fe(CN) anion sections in the lattice that are coordinated to K+ ions, and more of the lattice becomes exposed to the ether during the hexacyanoferrate-ether reaction.

Moreover, it appears from experiments that water acts as a chain-transfer agent in organic oxide polymerization with these catalysts. Therefore, the best catalyst for producing a polymer of high molecular weight is preferably one containing the least amount of water. One technique for removing water from the lattice structure is to displace the water with ether and remove the former by azeotropic distillation as shown by Example 28 below. The distillation is best carried out under vacuum at room temperature or thereabouts, i.e. 5 to 40 C., in order to prevent decomposition of the complex which may occur at elevated temperatures as discussed supra. In any event temperatures should not go above or 200 C. as discussed supra or below about 5 C. Hexane or other relatively low-boiling, inert, and essentially water-insoluble solvents such as heptane, toluene, benzene, pentane, 2- chlorobutane, cyclohexane, cyclopentane, ethylene chloride, and butane can be used in this distillation to separate the water from the ether as the distillate collects in a trap. In this way, all displaceable water is removed, however some water invariably remains trapped in the lattice. Other methods can be used to remove the water.

Also experiments indicate that chloride ions can inhibit the polymerization reaction (compare Examples 2B and C, and 6A and B below). Several methods of reducing the ionizable chlorine or other ionizable anions in the catalysts can be used. For example, in one method the catalyst is washed with a solution containing ether and water and the soluble chloride salt is removed. In another method the zinc hexacyanoferrate is prepared by reacting compounds such as Ca [Fe(CN) AlFe(CN) or with ZnCl The corresponding halide that forms and occludes on the crystals of Zn [Fe(CN) is then removed by the ether during the washing operation. When the preparations are made with K Fe(CN) ether-insoluble KCl is produced. However, when zinc hexacyanoferrate is prepared by the second method above, ether (organic treating agent) soluble CaCl AlCl or LiCl is produced. Also, where ions such as C1" are covalently bound to the complex, they do not apparently adversely aifect polymerization of the epoxides and oxetanes. In fact, the organic complexing materials like the chlorinated ethers can improve the efliciency of the catalyst, because the halogenated ethers can be displaced more readily by the epoxides and oxetanes to startpolymerization than the non-halogenated ethers.

When the catalyst is treated with polyethylene glycol ethers, a very active catalyst is obtained. They apparently form a chelate bond to the zinc ion. The formation of a chelate complex increases the driving force of the hexacyanoferrate-ether reaction and makes for a very open lattice because polymeric coordination through the oxygen atom is prevented, The coordination of Zn [Fe(CN) The use of diglyme and diglyet (dimethyl and diethyl ethers, respectively, of diethylene glycol) in the usual catalyst preparation was found to increase the efiiciency of the catalyst from 500 g. polymer/g. catalyst to 850 g. polymer/ g. catalyst.

Moreover, the addition of a substantial amount, such as 30-70% by volume of the total fluid, of the ether (or other organic treating agent) to freshly precipitated hexacyanoferrate in water greatly enhanced the activity of the catalyst, more than doubled amount of polymer per unit weight of the catalyst, (see Example 6C below): the efiiciency increases to 2000 g. polymer/g. catalyst. This catalyst also produces a polymer of very high molecular weight. According to elemental analysis, this complex may have some (ZnCl)+ ions in its structure.

It, thus, would appear that the best catalysts for oxide polymerization are those that contain the greatest amount of Zn ether bonds, rather than ZnOH O bonds, and the least amount of ionizable chloride. The more active catalysts, also, are prepared by using an excess of zinc chloride, and adding the K Fe(CN) solution to the chloride. Accordingly, it is seen that the present invention provides a novel way for polymerizing cyclic oxides and methods for enhancing the activity of the catalysts to obtain higher 'molecular weights, greater catalyst efiiciency and so forth.

The following examples will serve to illustrate the present invention with more particularity to those skilled in the art:

Example 1 Relatively pure zinc hexacyanoferrate (III) as catalyst K Fe(CN) (37.6 g., 0.114 mole) dissolved in 400 ml. water was added dropwise to a stirred solution containing ZnCl (77.2 g., 0.566 mole) in 150 ml. water. This is equivalent to using a 3.3fold excess of ZnCl The precipitated zinc hexacyanoferrate was thoroughly washed with hot (8595 C.) water and dried at 80 C. at 1 mm. Hg to give Zn [Fe(CN) -1.6H O with 0.2% Cl. Infrared analysis showed that 24% of the iron in the complex was reduced to Fe(II). This catalyst complex was then used to copolymerize PO and AGE as follows:

1 Based on weight of monomer(s) charged to the polymerization bottle.

Based on the weight of the mon0mer(s) charged to the polymerization bottle.

3 Mol percent of allyl glycidyl ether charged to the polym erization bottle and in the resulting polymer, balance being propylene oxide.

4 Intrinsic viscosity in isopropanol at 60 C.

If zinc hexacyanoferrate was prepared by combining (wt.) aqueous solutions of zinc chloride and potassium hexacyanoferrate (III), the resulting precipitate,

after drying under vacuum over P 0 was relatively inactive as a catalyst for epoxide polymerization due to excessive amount of ionizable chlorine being present and in contrast, if the zinc hexacyanoferrate was thoroughly washed with hot water as shown above, the dried precipitate did copolymerize propylene oxide and allyl glycidyl ether at C. However, the molecular weight of the polymer was relatively low, and the efiiciency of the catalyst was poor-only 200 g. polymer/g. catalyst.

Example 2.Dioxane Zinc hexacyanoferrate (III) as catalyst A. K Fe(CN) (28.3 g., 0.0861 mole) dissolved in 200 ml. water was added slowly to a solution containing zince chloride (19.35 g., 0.142 mole) in 75 ml. water. This was equivalent to using a 10 mol percent excess of zinc chloride. The precipitated zinc hexacyanoferrate was separated by centrifugation and washed four times with 200 ml. portions of anhydrous, peroxide-free dioxane and dried at room temperature at 1 mm. Hg. Elemental analysis showed that the complex was essentially and infrared analysis confirmed the presence of complexed dioxane. According to the infrared spectrum of the total iron in the complex 45% was Fe(II). This catalyst complex was then used to polymerize PO and to copolymerize PO and AGE as follow:

Washed with an additional volume of anhydrous dioxane before it was used for polymerization.

1 Based on weight of monomer(s) charged to the polymerizationbottle. b ts ased on the weight of the monomer(s) charged to the polymerization 3 Mol percent of allyl glycidyl ether charged to the polymerization bottle and in the resulting polymer, balance being propylene oxide.

4 Intrinsic viscosity in isopropanol at 6 C 5 mol percent propylene oxide; no in this run.

allyl glycidyl ether was used B. The zinc hexacyanoferrate prepared as in Example 2A above, was separated in a centrifuge tube and washed with only one 200-ml. portion of dioxane. Next, the precipitate was heated under vacuum at 35 C. in a solution containing 70 -vol. percent dioxane and 30 vol. percent n-hexane in a distillation assembly equipped with a Dean and Stark trap to collect the distilled water. In this way, loosely bonded water was displaced from the complex. When no additional water collected, the hexane was distilled, and the complex was recovered from the dioxane solution by centrifugation and dried at 1 mm. Hg at room temperature. This complex was essentially Z113 [Fe (CN)5]2'2.8C4H302' and contained 5.2% Cl, and only 11% of the iron was Fe(II). This catalyst was then used to polymerize PO and copolymerize PO and AGE as follows:

Mol Percent Percent Weight AGE 8 Percent Temp, Time, Conver- Vis.

0. Hrs. Cata- PBNA Feed Polysion lyst Iner 15 16 C. The zinc hexacyanoferrate prepared as in Example E. ZnCl (23.9 g., 0.175 mole) in 95 ml. water was 2A above was separated and washed with two ZOO-ml. added rapidly to a solution of K Fe(CN) (44.0 g., portions of 50 vol. percent dioxane in water and with 0.1336 mole) in 308 ml. water. This was equivalent to a two 200-ml. portions of pure dioxane. After drying at 14.5 mol percent excess (stoichiometric basis) of room temperature at 1 mm. Hg, the complex was used 5 K Fe(CN) The precipitated zinc hexacyanoferrate was for the following polymerization of PO and AGE: treated with dioxane and dried as described in Example 2A above. According to elemental analysis, this complex was essentially Zn [Fe(CN) -2.5C H O -1.lH O with f g: 4.3% 01, 3.9% K, and 61% of the iron was Fe(II). Bulk 0 2 1O density of powder: 0.248 g./ml. This complex copolymgzzg: 3 2 erized PO and AGE as follows:

M01 percent AGE: f -i c 35 Feed 31 Time, hrs. 24 Polymer 3 4 Percent wt. catalyst 0.2

Percent conversion 48 Percent PBNA 2 Vis. 3 M01 percent AGE:

Feed 3.0 Based on weight of mon0mer(s) charged to the polymeri- Polymer 3.0

zation bottle. P t 9 Based on the weight of the monomer(s) charged to the ercen converslon polymerization bottle. Vis, 4.2

M01 percent of allyl glycidyl ether charged to the polymerizaxtiolneigitiitzilg and in the resulting polymer, balance being iiBaszdttoln weight of monomer(s) charged to the polymeriprop e za on o e.

Intrinsic viscosity in isopropanol at 60 C. Based on the weight of the monomer(s) charged to the polymerization bottle.

hiol percent of allyl glycidyl ether charged to the polym- A part of this catalyst preparation was dried by azeo- 55 53533 53 23 m the resultmg polymer balance being tropic distillation as described in Example 2B above. This Intrinsic Viscosity in isopwpalml at a complex was similar in composition to the above 2B In solution (20 wt. percent monomer), the following prepa xcept that it had only 1.0% Ci, but 55% of copolymers were prepared from this catalyst as follows:

Mol Percent Temp., Time, Percent Weight AGE I Percent Solvent c. Hrs, Conver- Vis.

Cata- PBNA Feed Polysion lyst mer p ana- 43 0.2 0.2 a 2.3 51 3.1 Pentane. 35 48 0.2 0.2 3 4.0 60 2.9

1 Based on weight of monomer(s) charged to the polymerization bottle.

2 Based on the weight oi the monomer(s) charged to the polymerization bottle.

3 Mol percent of allyl glycidyl other charged to the polymerization bottle and in the resulting polymer, balance being propylene oxide.

4 Intrinsic viscosity in isopropanol at 60 C.

ill? iron was UD- The -l y Was Then used to P Y F. The zinc hexacyanoferrate prepared using a 3.3-fold r ze P and copolymfiflze PO and AGE as follows! excess of ZnCl as in Example 1, above, was treated with Percent weight fig f Percent dioxane and dried as described in Example 2A above.

Temp., Time, Convervis. Infrared analysis indicated that this complex contained a gg f PBNA Feed about 3 moles of dioxane per mole of Zn [Fe(CN) 35 24 Q2 (L15 3 24 49 and 63% of the total iron was Fe(II). This complex (5) 36 copolymerized PO and AGE to the solid stage twice as jg gfl gg of mummefls) c arged to the pmymer fast as the complex in Example 2A, above:

Based on the weight of the monomer(s) charged to the polymerization bottle.

3 M01 percent of allyl glycidyl ether charged to the polymerization bottle and in the resulting polymer, balance being iii ti' i fis g y igcosity in isopropanol at 60 C 50 Tfamp', o C 35 5 100 mol percent propylene oxide; no allyl glycidyl ether Tune 24 was used in this run. Percent wt. catalyst 1 0.2 D. 21101 (5.97 g., 0.0438 mole) in 78 ml. water was P r ent Wt. PBNA 2 0.2 added slowly to a solution of K Fe(CN) (14.3 g., 0.0434 M01 percent AGE: 3 mole) in 38 ml. water. This was equivalent to a 48.6 mol Feed 3.0 percent excess (stoichiornetric basis) of K Fe(CN) The P l 0 precipitated zinc hexacyanoferrate was treated with diox- Percent conversion 80 ane and dried as described in Example 2A above. Yield 4 of dioxane complex: 14.9 g. Bulk density of powder:

0.287 g./ml. The catalyst was then used to polymerize PO and to copolymerize PO and AGE as follows. Based on weight of monomer(s) charged to the polymerization bottle. M01 Percent iBased (31 th; gz'lelght of the monomer-(s) charged to the p0 ymeriza on o e. Tam Time Percent Welght AGE 3 53 x53; vis 4 Mol percent of allyl glycidyl ether charged to the polym- 0 D" Hrs PBNA: *Feed Po1y Sim errzation bottle and in the resulting polymer, balance being y t 1 met propylene oxide.

Intrinsic viscosity in isopropanol at 60 C. 25 24 0.2 0.2 3.0 2.6 77 4.4 35 24 0. 2 0. 2 3. 0 3. 0 86 4. 0 35 24 0.2 0.2 6.0 5.3 83 4.1 35 24 0.2 0.2 91 4.0

G. ZnCl (9.68 g., 0.071 mole) dissolved in ml. water 1 Based on Weight of monomer (5) charged to the polymeiizationbottle' O 1 Based on the weight of the monomer(s) charged to the polymerization was added rapldly to surfed Solutlon of K3136 8 bottle- 52.0 0. 2

8 Mel percent oi allyl glycidyl ether charged to the polymerization g 158 mole) m 00 ml of Water Thls 1S botltlet andin the regulitinlg polymer,l balsam?) being propylene oxide. equlvalent to a 33-fold excess of 3 )6- The P n rinsie viscosi y sopropano a 5 mol percent propylene oxide; no allyl glycidyl ether was used 2 Hate w separated by centnfuglatlon and washed four n this run. 75 times with 400-ml. volumes of dioxane. After vacuum 17 drying the complex copolymerized PO and AGE as follows Catalyst was washed with two additional volumes of dioxane before it was used for polymerization.

l Based on weight of monomer(s) charged to the polymerizationbottle b n]; ased on the weight of the monomer(s) charged to the polymerization 3 M01 percent of allyl glycidyl ether charged to the polymerization bottle and in the resulting polymer, balance being propylene oxide.

4 Intrinsic viscosity in isopropanol at 60 C.

H.A mixture of K Fe(CN) (26.5 g., 0.0818 mole) and K Fe(CN) -3H O (1.8 g., 0.0043 mole) was dissolved in 200 ml. water and added dropwise to a solution containing ZnCl (19.3 g., 0.142 mole) in 75 ml. water. After the precipitate was separated, it was washed four times with a total of 660 ml. dioxane. According to infrared analysis, the dried precipitate contained about 3 moles of dioxane/mole of Zn [Fe(CN) and 65% of the total iron was Fe(ll). This precipitate or catalyst was 1 Based on weight of mouomer(s) charged to the polymerization bottle.

Based on the weight of the monomer(s) charged to the polymerization bottle.

3M01 percent of allyl glycidyl ether charged to the polymerization bottle and in the resulting polymer, balance being propylene oxide.

Intrinsic viscosity in isopropanol at 60 C.

I. K Fe(CN) (7.08 g., 0.0215 mole) was dissolved in 50 ml. Water and added slowly to a solution of Zn(NO -6H O (17.38 g., 0.0584 mole) in 48 ml. water. This is equivalent to an 81 mole percent excess of Zn(NO The precipitate was washed with dioxane and dried as in example 2A above. Analysis by infrared showed that dioxane was incorporated, although less than the normal amount, and 46% of the total iron in the complex was Fe(II). This complex was less eifective as a catalyst in the copolymerization of PO and AGE as shown below:

1 Based on weight of monmer(s) charged to the polymerization bottle.

Based on the weight of the monomer(s) charged to the polymerization bottle.

M01 percent of allyl glycidyl ether charged to the polymerization bottle and in the resulting polymer, balance being propylene oxide.

4 Intrinsic viscosity in isopropanol at 60 C.

Example 3 Iron H exacyanoferrate A. K Fe(CN) -3H O (44.2 g., 0.105 mole) in 295 ml. water was added to a 10 mol percent excess of FeCl;; (24.9 g., 0.1536 mole) in 167 ml. water and Prussian Blue precipitated. One portion of this blue precipitate was dried at room temperature over P 0 at 1 mm. Hg.

This complex was used to copolymerize AGE and PO as follows:

Temp., C. Time, hrs. 96 Percent wt. catalyst 1 0.2 Percent wt. PBNA 2 0.2 M01 percent AGE: 3

Feed 1 3.0

Polymer 1.6 Percent conversion 29 Vis. 0.9

Based 'on weight of mon0mer(s) charged to the polymerization bottle.

Based on the weight of the monomer(s) charged to the polymerization bottle.

3 M01 percent of allyl glycidyl ether charged to the polymerization bottle and in the resulting polymer, balance being propylene oxide.

4 Intrinsic viscosity in isopropanol at 60 C.

B. Another portion of the blue precipitate from EX- ample 7A above was Washed with four volumes of dioxane in a centrifuge tube. According to infrared analysis of the vacuum-dried precipitate, little or no dioxane was incorporated in the hexacyanoferrate. Polymerization of PO and AGE with this complex catalyst is summarized below:

Temp, C. 80 Time, hrs. 48 Percent wt. catalyst 1 0.2 Percent wt. PBNA 2 0.2 M01 percent AGE: 3

Feed 3.0

Polymer 3.0 Percent conversion 66 Vis. 1.0

Based on weight of mon0mer(s) charged to the polymerization bottle.

-'Based on the Weight of the monomer(s) charged to the polymerization bottle.

Mol percent of allyl glycidyl ether charged to the polymerization bottle and in the resulting polymer, balance being propylene oxide.

Intrinsic viscosity in isopropau'ol at 60 C.

C. A 15% aqueous solution of K Fe(CN) (18.4 g., 0.056 mole) was added to a 15% aqueous solution of FeC1 (10.0 g., 0.062 mole), which was equivalent to a 10 mol percent excess of the latter. The precipitate was brown at first but rapidly turned green as it evolved chlorine. The precipitate was separated by centrifugation and washed with four volumes of dioxane. Infrared analysis of the vacuum-dried complex showed that no dioxane was incorporated and that most of the iron was in some resonance-stabilized form between Fe+ and Fe, identical to the form in Example 7B, above. This complex copolymerized AGE and PO as follows:

Based on weight of monomer(s) charged to the polymer'ization bottle.

Based on the weight of the monomer(s) charged to the polymerization bottle.

3 Mol percent of allyl glycidyl ether charged to the polymerization bottle and in the resulting polymer, balance being propylene oxide.

4 Intrinsic viscosity in isopropanol at 60 C.

In 'Examples 1 to 3, above, the dried catalyst, generally an equal weight of PBNA (phenyl S-naphthylamine), and a magnetic stirring bar were charged into a dry, crowncapped beverage bottle. The bottle was capped and evacuated at 1 mm. Hg for one hour to remove any occluded moisture and, finally, the monomers were charged into the evacuated bottle. Polymerization was carried out in Example 4 A catalyst having the general base formula was prepared by methods similar to the above. After separation of the catalyst from the water, one portion was washed with acetone and the other portion was washed with dioxane. The thus treated catalysts were then used for the polymerization of propylene oxide generally according to the preceding methods as follows:

Ag Fe(CN) was reacted in H O with CaCl to give CaFe(CN) The calcium ferricyanide was then reacted in H O with ZnCl to give a zinc ferricyanide precipitate which was washed four times with dioxane. 0.1 g. of this dioxane Washed Zn [Fe(CN) catalyst was placed in a polymerization bottle, and 10 g. (11.2 ml.) of oxetane was added. Polymerization was conducted in the capped polymerization bottle without solvent under nitrogen for 77 hours at 80 C. to give a yield of 92% polymer. The resulting oxetane polymer was a fairly crystalline solid and became sticky when handled in the fingers. It had a. viscosity in isopropanol of 0.234 and in ash of 0.49%.

Example 6 Samples of propylene oxide-allyl glycidyl ether copolymers prepared generally according to the foregoing examples in which zinc hexacyanoferrate was the catalyst, and wherein phenyl beta naphthyl amine as an antioxidant was included in the polymerization recipe in an amount by weight about equal to the catalyst, and dioxane or diglyme Was the organic complexing agent were processed, compounded and cured. In processing, these copolymers (raw gum stocks) were glass clear, possessed an appreciable nerve and showed signs of cold flow when subjected to permanent extension. Their (raw gum stock) mill behavior was excellent with the formation of the desired rolling bank. Dispersion of carbon black in the copolymers proceeded normally and reached a level showing a black glass clear cut (similar to natural rubber). These copolymers were then compounded, cured (at 300 to 320 F. for from 11 to 220 minutes, most at 90 minutes) and tested as shown in Table A below:

TABLE A.-RUNS A THROUGH J (AMOUNTS BY WEIGHT) Ingredients Run A Run B Run 0 Run D Run E Run F Run G Run H Run I Run J Copolymer of Propylene Oxide and allyl glycidyl her 1 100.0 1 100.0 2 100. 0 2 100.0 3 100. 0 2 100.0 2 100.0 2 100.0 2 100.0 2 100.0 NBC Antioxidant 1. 0 0 1. 0 l. 0 1. 0 1.0 ISAF Black 0 40. 0 HAF Black 40.0 40.0 0 0. 0 .0 40.0 40. Zinc Oxide 5. 0 5.0 .0 3.0 3.0 3.0 Stearic Acid 1- 0 1. 0 1. 0 1. 0 1. 0 MBT 1. 5 2. Tellurac 5 l 5 DOTG 5 2. Santocure 7 TMTMS (Mouex) 1.2 1. 2 0.9 Sulfur 1. 5 1. 5 0. 8 0. 8 0. 8 0. 8 1. 2 1. 2 Raw Polymer ML4 521 42 37 48 50 Solution Viscosity (1;) 3. 1 3. 1 6. 7 5. 0 4. 2 3. 7 5. 0 6. 5 Actual unsaturation, mol percent Allyl glycidyl ether in copolymer 2. 1 2. 1 1. 7 1 9 2. 5 3. 9 4. 0 7. 8 4. 4 Rate of vulcanization 0. 8 0. 6 0. 6 O. 9 0. 6 1. 1 Time needed to reach 300% modulus plateau,

minute 50 180 90 40 180 40 40 40 Original Test Specimens-Testing at Room Temperature Hardness, Shore A. 69 69 59 56 56 60 60 58 66 65 Modulus 300%, psi. 1, 350 1, 200 700 600 700 800 800 250 1, 175 950 Tensile at break, 1.7.8.1... 2, 000 1, 300 2, 2, 100 2,050 1, son 2, 000 1,900 2, 000 2,200 Percent Elongation at break 475 450 800 850 700 650 i 650 900 425 600 Tear, p.i. (Crescent) 300 350 410 Tensile break set 22/32 8 4 5 Goodrich Flexometer:

Percent DOS 1.5 2.1 2.7 1.1 1.8 HBU, F 59 63 67 49 56 Pico abrasion index 102 108 Original Test SpecimensTesting at 212 F.

Modulus at 300% E., p.s.i 1, 250 1, Tensile at break,p.s.i 1,400 1,200 Percent Elongation at brea 350 350 Tear, p.i. (Crescent) 320 200 300 Goodrich Flexometer:

Percent DCS. 9.1 3. 9 5.6 HBU, 56 36 39 Compression Set, percent 41. 5 42. 1 41. O 45. 8 37. 5 49. 2

Original Test SpecimensLow Temperature Tests 25 percent R from 250% Elongation at 61 60 59 50% -56 -57 75% 51 52 TM at- -75 C.() 17. 0 95. 5 "0 C--- 9.1 28.6 -65 2.7 8.0 60 C--- 2. 3 2.0

l Dioxane as complexing agent.

2 Diglyme as complexing agent.

8 Contains as active ingredient nickel dibutyl dithiocarbamate. 4 Z-mercapto benzothiazole.

5 Tellurium diethyl dithiocarbemate.

6 Di-ortho-tolylguanidine.

1 N-cyclohexyl-Z-benzothiazole sulfenamide. 8 Tetramethyl thiuram monosultide.

9 Mooney viscosity, large rotor.

0t raw gum stock, in isopropanol at 60 0. l1 Torsional modulus, Clash-Berg.

21 The abrasion resistance data of these copolymers show that they have a good level of resistance against abrasion. Stress retraction data at low temperatures indicate that the degree of crystallinity in these polymers is very low, and they do not stilfen until at a very low temperature.

The TR curves are steep, and the stiffening up occurs at about 65 C. as judged from the Clash-Berg curves. T-SO is close to 56 C. This means that these polymers can be used in a number of applications at very low temperatures. The data on hot tear of the polymers is satisfactory and the increase in test temperature to 205 F. decreases the moduli of the copolymers very little.

It is to be understood that in accordance with the patent laws and statutes, the particular compositions, products and methods disclosed herein are presented for purposes of explanation and that various modifications can be made in these compositions, products and methods without departing from the spirit of the present invention.

What is claimed is:

1. A composition comprising a double metal cyanide complex compound, wherein one of the metals of said complex compound is selected from the group consisting of Zn (II), Fe (II), Fe (III), Co (II), Ni (II), Mo (IV), Mo (VI), Al (III), V (IV), V (V), Sr (II), W (IV), W (VI), Mn (II), and Cr (III), and mixtures thereof, and wherein the other metal of said complex compound is selected from the group consisting of Fe (II), Fe (III), Co (II), Co (III), Cr (II), Cr (III), Mn (II), Mn (III), V (IV), and V (V), and mixtures thereof, containing, in an amount suflicient to increase the activity of said complex for the polymerization of organic cyclic oxides, at least one organic material selected from the group consisting of (a) an acyclic aliphatic saturated monoether consisting of carbon, hydrogen and oxygen or carbon, hydrogen, oxygen and chlorine and containing only ether functionality,

(b) an ester consisting of carbon, hydrogen and oxygen and containing only ester functionality, and

(c) a cyclic ether consisting of carbon, hydrogen, and

oxygen and containing only ether functionality, and said organic material having up to 18 carbon atoms, being inert to polymerization by said compound and further being complexed with said compound, said compound containing at least a majority of CN- bridging groups.

2. A composition useful in polymerizing organic cyclic oxides and having the general formula:

where D is selected from the group consisting of )b and )r( )t]b,

where M is at least one metal selected from the group consisting of Zn (II), Fe (II), Fe (III), Co (II), Ni (II), Mo (IV), Mo (VI), Al (III), V (IV), V (V), Sr (II), W (IV), W (VI), Mn (II), and Cr (III),

where M is at least one metal selected from the group consisting of Fe (II), Fe (III), Co (II), Co (III), Cr (11), Cr (III), Mn (II), Mn (III), V (IV), and V (V),

where X is at least one material selected from the group consisting of F, Cl, Br, I OH-, NO, CO, H O, N0 C 031 80 CNO, CNS-, NCO, and NCS,

where R is at least one organic material selected from the group consisting of (a) an acylic aliphatic saturated monoether consisting of carbon, hydrogen and oxygen or carbon, hydrogen, oxygen and chlorine and containing only ether functionality,

(b) an ester consisting of carbon, hydrogen and oxygen and containing only ester functionality, and

(c) a cyclic ether consisting of carbon, hydrogen,

and oxygen and containing only ether functionality, said organic material having up to 18 carbon atoms, being substantially water miscible and being inert to polymerization by, and being complexed with, M (D) -(H O) of said formula,

where a, b and c are numbers whose values are functions of the valences and coordination numbers of M and M, the total net positive charge on M times a being essentially equal to the total net negative charge on (D) times c,

where r is greater than t,

where r is a number,

where t is a number,

where d is zero or a number, and

where e is a number sufli cient to increase the activity of M,,(D) -(H O) for the polymerization of said organic cyclic oxides.

3. A composition according to claim 2 where M is Zn (II), M is Fe (II) and Fe (III), t is zero, and the sum of the coordinating atoms of H 0 and R is equal to from about 0.1 to 5 g.-atoms per g.-atom of M.

4. A composition according to claim 2 where said R is a cyclic ether.

5. A composition according to claim 2 where said R is dioxane.

6. The method which comprises repeatedly washing a double metal cyanide complex compound, wherein one of the metals of said complex compound is selected from the group consisting of Zn (II), Fe (II), Fe (III), Co (II), Ni (II), Mo (IV), Mo (VI), Al (III), V (IV), V (V), Sr (II), W (IV), W (VI), Mn (II) and Cr (III), and mixtures thereof and wherein the other metal of said complex compound is selected from the group consisting of Fe (II), Fe (III), Co (II), Co (III), Cr (II), Cr (III), Mn (II), Mn (III), V (IV), and V (V), and mixtures thereof, said cyanide complex compound having a majority of CN- bridging groups, with an amount sufficient to increase the activity of said complex for the polymerization of organic cyclic oxides of at least one organic material selected from the group consisting of (a) an acyclic aliphatic saturated monoether consisting of carbon, hydrogen and oxygen or carbon, hydrogen, oxygen and chlorine and containing only ether functionality,

(b) an ester consisting of carbon, hydrogen and oxygen and containing only ester functionality, and

(c) a cyclic ether consisting of carbon, hydrogen and oxygen and containing only ether functionality,

said organic material having up to 18 carbon atoms, being inert to polymerization by said compound and further being complexed with said compound, and drying said organic material complexed compound.

7. The method which comprises mixing with a firstnamed compound comprising a precipitate having the general formula: M (D) '(H O) in aqueous media, an organic material, removing said organic material treated precipitate from said aqueous media, repeatedly washing said treated precipitate with said organic material, and vacuum drying said washed treated precipitate to provide a second-named compound having the general formula: M,,(D) (H O) (R) where in said formulae:

R is said organic material,

D is selected from the group consisting of M'(CN) and )r( )tla,

M is at least one metal selected from the group consisting of Zn(II), Fe(II), Fe(III), Co(II), Ni(II), Mo(IV), Mo(VI), AI(III), V(IV), V(V), Sr(II), W(IV), W(VI), Mn(II) and Cr(III),

M is at least one metal selected from the group consisting of Fe(II), Fe(III), Co(II), Co(III), Cr(II), Cr(III), Mn(II), Mn(III), V(IV), and V(V),

X is at least one material selected from the group consisting of F1 Cl, Br", 1*, OH-, NO, 0 CO,

23 H O, NO C 033 SO, CNO", CNS, NCO, and NCS,

a, b and c are numbers whose values are functions of the valences and coordination numbers of M and M, the total net positive charge on M times a being essentially equal to the total net negative charge on (D) times 0,

r is greater than t,

r is a number, t is a number,

d is zero or a number, and e is a number sufiicient to increase the activity of said first-named compound for the polymerization of organic cyclic oxides,

said organic material being inert to polymerization by and being complexed with said first-named compound, having up to 18 carbon atoms, being substantially water miscible and being selected from the group consisting of (a) an acyclic aliphatic saturated monoether consisting of carbon, hydrogen and oxygen or carbon, hydrogen, oxygen and chlorine and containing only ether functionality,

(b) an ester consisting of carbon, hydrogen and oxygen and containing only ester functionality, and

(c) a cyclic ether consisting of carbon, hydrogen,

and oxygen and containing only ether functionality.

8. The method according to claim 7 where said secondnamed compound is dried in a vacuum at a temperature of from about to 200C.

9. The method according to claim 8 where M is Zn(H), M is Fe(H) and Fe(III), t is zero, and the sum of the coordinating atoms of H 0 and R is equal to from about 0.1 to 5 g.-atoms per g.-atom of M.

10. The method according to claim 7 where said R is a cyclic ether.

11. The method according to claim 7 where said R is dioxane.

12. A composition according to claim 2 in which M is at least one metal selected from the group consisting of zinc (II), iron (II), cobalt (H) and nickel (II) and where M is at least one metal selected from the group consisting of iron (H), iron (III), cobalt (HI) and chromium (III).

13. The method according to claim 7 in which M is at least one metal selected from the group consisting of zinc (II), iron (II), cobalt (H) and nickel (H) and where M is at least one metal selected from the group consisting of iron (II), iron (HI), cobalt (HI) and chromium (HI).

References Cited UNITED STATES PATENTS 4/1939 Van Wirt et a1 13458 5/1957 Verbeek et a1. 106-34 OTHER REFERENCES The Chemistry of the Ferrocyanides, American Cyanarnid Co., New York, N.Y., 1935, pp. 62, 65, 66. 

